abstract
The manuscript focuses on manufacturing of new in situ foam-filled tubes (in situ FFTs) of Al-alloys including the foaming stage and studying their mechanical behaviour under quasi-static and dynamic bending loadings. The composite structures were manufactured by the powder compact foaming technique. These structures are fabricated by heating foamable precursor material pieces above their solid temperature inside thin-walled tubes. Different manufacturing parameters were appropriately adjusted based on preliminary experiments. The mechanical crushing behaviour and failure mechanisms were assessed by three-point bending experiments supported by infrared thermography. The bending performance of in situ FFTs and ex situ foam-filled heat treated tubes (ex situ FFTTs) were compared with that of empty tubes subjected to heat treatment. The observed results have been explained in terms of the structural changes in the thermally treated tubes, the surface roughness derived from oxidation, and the dimensions of the interface gap between the two components in the composite structures. The in situ FFTs composite structures confirmed stable and controllable deformation and a promising energy absorption capability. (C) 2014 Elsevier Ltd. All rights reserved.
keywords
SILICONE PORE FILLER; WALL MICROSTRUCTURE; CELLULAR STRUCTURE; ENERGY-ABSORPTION; STEEL TUBES; KINETICS
subject category
Materials Science
authors
Duarte, I; Vesenjak, M; Krstulovic-Opara, L; Anzel, I; Ferreira, JMF
our authors
acknowledgements
The results reported in this paper were supported by the Portuguese project QREN/ValeI&DT/nr.19025/MJAmaral, bilateral project BI-HR/012-13-042 and the framework of the operation entitled